Bézier Curves-Based Optimal Trajectory Design for Multirotor UAVs with Any-Angle Pathfinding Algorithms

Satai, Haitham A L; Zahra, Musaddak Maher Abdul; Rasool, Zaid I.; Abd-Ali, Ridhab Sami; Pruncu, Catalin I.

doi:10.3390/s21072460

Cited by 17 publications

(4 citation statements)

References 40 publications

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“…4) Path Optimization: Path optimization is a method for determining a viable, optimal or near-optimal, shortest, smoothest, and least-expensive route between the initial location and a destination of choice point while considering certain operational restrictions [116], [117]. Significant challenges to UAV optimal path planning include collision avoidance, route length, time efficiency, cost efficiency, energy efficiency, and completeness [36].…”

Section: B Uavs Collision Avoidance Algorithmsmentioning

confidence: 99%

Comprehensive Review of Drones Collision Avoidance Schemes: Challenges and Open Issues

Rezaee,

Hamid,

Hussin

et al. 2024

IEEE Trans. Intell. Transport. Syst.

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In the contemporary landscape, the escalating deployment of drones across diverse industries has ushered in a consequential concern, including ensuring the security of drone operations. This concern extends to a spectrum of challenges, encompassing collisions with stationary and mobile obstacles and encounters with other drones. Moreover, the inherent limitations of drones, namely constraints on energy consumption, data storage capacity, and processing power, present formidable obstacles in developing collision avoidance algorithms. This review paper explores the challenges of ensuring safe drone operations, focusing on collision avoidance. We explore collision avoidance methods for UAVs from various perspectives, categorizing them into four main groups: obstacle detection and avoidance, collision avoidance algorithms, drone swarm, and path optimization. Additionally, our analysis delves into machine learning techniques, discusses metrics and simulation tools to validate collision avoidance systems, and delineates local and global algorithmic perspectives. Our evaluation reveals significant challenges in current drone collision prevention algorithms. Despite advancements, critical UAV network and communication challenges are often overlooked, prompting a reliance on simulation-based research due to cost and safety concerns. Challenges encompass precise detection of small and moving obstacles, minimizing path deviations at minimal cost, high machine learning and automation expenses, prohibitive costs of real testbeds, limited environmental comprehension, and security apprehensions. By addressing these key areas, future research can advance the field of drone collision avoidance and pave the way for safer and more efficient UAV operations.

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Section: B Uavs Collision Avoidance Algorithmsmentioning

confidence: 99%

Comprehensive Review of Drones Collision Avoidance Schemes: Challenges and Open Issues

Rezaee,

Hamid,

Hussin

et al. 2024

IEEE Trans. Intell. Transport. Syst.

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show abstract

“…Two control points define a Bezier curve as a linear curve (first-order curve-a straight line), three control points define a quadratic curve (second-order curve), four control points define a cubic curve (third-order curve). In the developed software complex, third-order Bezier curves are used to determine the shape of the fiber [32]:…”

Section: Porous Structures Modelsmentioning

confidence: 99%

Information-Analytical Software for Developing Digital Models of Porous Structures’ Materials Using a Cellular Automata Approach

Lebedev,

Uvarova,

Menshutina

2023

Technologies

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An information-analytical software has been developed for creating digital models of structures of porous materials. The information-analytical software allows you to select a model that accurately reproduces structures of porous materials—aerogels—creating a digital model by which you can predict their properties. In addition, the software contains models for calculating various properties of aerogels based on their structure, such as pore size distribution and mechanical properties. Models have been implemented that allow the description of various processes in porous structures—hydrodynamics of multicomponent systems, heat and mass transfer processes, dissolution, sorption and desorption. With the models implemented in this software, various digital models for different types of aerogels can be developed. As a comparison parameter, pore size distribution is chosen. Deviation of the calculated pore size distribution curves from the experimental ones does not exceed 15%, which indicates that the obtained digital model corresponds to the experimental sample. The software contains both the existing models that are used for porous structures modeling and the original models that were developed for different studied aerogels and processes, such as the dissolution of active pharmaceutical ingredients and mass transportation in porous media.

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“…Al Satai et al [7] propose using any-angle path-finding algorithms like Basic Theta*, Lazy Theta*, and Phi* paired with Bézier curves to smooth the generated paths to be converted to a flyable trajectory. This is a novel approach to efficiently construct optimal trajectories, but may be limited by its computational complexity for real-time performance.…”

Section: Introductionmentioning

confidence: 99%

Online Deterministic 3D Trajectory Generation for Electric Vertical Take-Off and Landing Aircraft

Mbikayi,

Steinert,

Heimsch

et al. 2024

Aerospace

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The use of non-piloted eVTOL aircraft in non-segregated airspace requires reliable and deterministic automatic flight guidance systems for the aircraft to remain predictable to all the users of the airspace and maintain a high level of safety. In this paper we present a 3D trajectory generation module based on clothoid transition segments in the horizontal plane and high order polynomial transition segments in the vertical plane. The expressions of the coefficients of the polynomial are derived offline are used to generate the trajectory online, making the system capable of running in real time without requiring enormous computational power. For the horizontal plane, we focus on the flyby transition, and therefore present a thorough analysis of the flyby geometry and the limitations linked to this geometry and the construct of three-segment trajectory generation around a fixed turn rate. We present feasible solutions for these limitations, and show simulation results for the combined horizontal and vertical plane concepts, allowing the system to generate complex 3D trajectories.

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Bézier Curves-Based Optimal Trajectory Design for Multirotor UAVs with Any-Angle Pathfinding Algorithms

Cited by 17 publications

References 40 publications

Comprehensive Review of Drones Collision Avoidance Schemes: Challenges and Open Issues

Comprehensive Review of Drones Collision Avoidance Schemes: Challenges and Open Issues

Information-Analytical Software for Developing Digital Models of Porous Structures’ Materials Using a Cellular Automata Approach

Online Deterministic 3D Trajectory Generation for Electric Vertical Take-Off and Landing Aircraft

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